KR20180053323A - Double Variable Capacity Compressor and Air Conditioning System Including It - Google Patents

Abstract

A variable capacity compressor (50) includes a first cylinder group (10) and a second cylinder group (20), and the first cylinder group The group 10 includes a first cylinder 11 communicating with the first sliding slot 12 and the first sliding slot 12 and having a first through hole 12a through which a high pressure gas is introduced; A first sliding vane (14) having a positioning groove (15) in contact with an outer circumferential surface of a first roller (30) eccentrically installed; (16) having an upper end communicating with the first through hole (12a) and a lower end capable of selectively introducing a high-pressure gas or a low-pressure gas to have a lock position or an unlock position, and the second cylinder group 20 includes a second sliding vane 23 which is always in contact with the outer circumferential surface of the second roller 40 to be eccentrically installed. The dual variable capacity compressor (50) and the air conditioning system having the dual variable capacity compressor (50) can stably switch the double variable capacity mode and the single variable capacity mode.

Description

Double Variable Capacity Compressor and Air Conditioning System Including It

The present invention relates to a dual variable capacity compressor and an air conditioning system having the same.

As the demand for the energy efficiency efficiency level in the country is improved day by day, the existing dual variable capacity compressor solves the problem that the low temperature heating ability is lowered by increasing the enthalpy by the gas replenishment, so that the heating capacity of the air conditioner is satisfied. However, since the double variable capacity compressor performs compression through the high pressure cylinder and the low pressure cylinder, the pressure ratio is large in a load operation mode (name cooling, name heating, national standard operation mode, low temperature operation mode, etc.). By using double compression, the pressure ratio can be effectively distributed so that both the high-pressure cylinder and the low-pressure cylinder can operate reasonably. In the light load operation mode (for example, the IPLV operation mode, the intermediate operation mode, etc.) of the air conditioning system, by performing the medium to low pressure switching through the variable capacity means to realize the single variable capacity operation by the single cylinder, This low problem can be solved effectively, but the medium to low voltage switching is greatly affected by the operating mode and the switching may fail due to a malfunction of the pin. Specifically, in the conventional method, the end portion of the sliding slot of the cylinder communicates with the intermediate chamber through the diaphragm gas guide slot and the gas guide slot of the lower cylinder, and performs the medium to low pressure switching by the variable capacity means. In the dual operating mode, the intermediate chamber is a medium pressure, and the pressure difference that the pin receives is the pressure difference between the medium and low pressures. There is a possibility that the dual mode is not normally operated because the medium and low pressure difference is smaller than the spring force.

The conventional compressor has various locking means for controlling the movement of the sliding vane. One of them is to control the movement of the pin by turning the electromagnetic on and off. It is necessary to install an electromagnet, its reliability is important, and the overall structure and control of the compressor is complicated. Another method is to control the intake pressure, The sliding vane is locked or the sliding vane is operated normally by switching the exhaust pressure and controlling the movement of the pin together with the spring force. Since the spring is installed in the head portion of the pin to increase the position restricting structure, Another object of the present invention is to provide a sliding vane in which the end portion of the sliding slot of the separating cylinder is a sealing structure and the pressure in the distal end portion of the sliding slot is changed, The pin has a pressure difference, Only it is possible to limit the movement of the sliding vane, a pin mounted to the lower flange, and that is equipped with a complex, a method of mounting the noise within the chamber of the lower flange limit position through the muffler is high demand for the hardness of the silencer. In addition, in this patent, high-pressure oil is drawn in from the oil tank to ensure lubrication and sealing of the sliding vane and used at a high pressure, but there is a concern that oil is accumulated in the sliding slot and power consumption is increased during operation of the sliding vane .

SUMMARY OF THE INVENTION The main object of the present invention is to provide a dual variable capacity compressor which is stable and safe in switching between single and double variable capacities and an air conditioning system having the same.

In order to achieve the above object, one aspect of the present invention is a double variable capacity compressor including a first cylinder group and a second cylinder group arranged along the axial direction of a double variable displacement compressor, A first cylinder communicating with the first sliding slot and the first sliding slot and provided on the wall surface of the first cylinder along the radial direction of the first cylinder and having a first through hole for introducing the high pressure gas; A first sliding vane movably installed in the first sliding slot, the first sliding vane being in contact with an outer circumferential surface of a first roller eccentrically installed and having a positioning groove; And a lower end portion of the lower end portion is capable of selectively introducing a high-pressure gas or a low-pressure gas so as to be inserted into the positioning groove so as to be in a lock position or a position where the first sliding vane is locked at a position away from the rotation center of the first roller Locking means having an unlocking position in which the second sliding group is separated from the crystal groove, the second group of cylinders includes a second cylinder in which a second sliding slot is installed; And a second sliding vane which is movably installed in the second sliding slot and always in contact with the outer circumferential surface of the eccentrically mounted second roller.

Furthermore, the locking means includes a pin whose upper end is in communication with the first through hole and whose lower end is capable of selectively introducing the high-pressure gas or the low-pressure gas.

Further, the first cylinder has an inlet port communicating with the main intake port, and an elastomer which is in contact with the lower end of the pin. The lower end of the pin communicates with the inlet port, and the inlet port can selectively introduce the high- or low- pressure gas.

Further, the first cylinder group further includes a flange provided under the first cylinder, wherein the flange is provided at a position corresponding to the positioning groove with a mounting groove provided along the axial direction of the double variable displacement compressor, And is movably installed in the mounting groove.

Further, the flange has a gas guide hole communicating with the first sliding slot through the intake port.

Further, the first cylinder group further includes a lower cover plate connected to the bottom of the flange, wherein the lower cover plate has a gas guide slot, the intake port communicating with the lower end of the pin through the gas guide hole and the gas guide slot of the flange, .

Furthermore, on the side wall of the noise chamber of the flange, a third through hole communicating with the intake port of the second cylinder is provided.

Further, the first cylinder is provided with a through hole, and the flange is provided with a connection hole communicating with the noise chamber of the flange, and the through hole communicates with the noise chamber of the flange.

Further, a fourth through hole and a fifth through hole are formed in the flange, a lower cover plate has a gas guide slot, and a fourth through hole is formed between the fifth through hole and the gas guide of the lower cover plate of the first cylinder group Through the slot, and the fourth through hole can selectively introduce the high-pressure gas or the low-pressure gas.

Furthermore, the second cylinder is provided on the wall surface of the second cylinder along the radial direction of the second cylinder and has a sixth through hole for introducing the high-pressure gas, and the sixth through hole communicates with the second sliding slot.

According to another aspect of the present invention, there is provided an air conditioning system including the double variable displacement compressor.

Furthermore, the air conditioning system further includes an enthalpy increasing device in communication with the dual variable displacement compressor, a pressure stabilizer and a distributor and a dual variable capacity compressor, an enthalpy increasing device, a pressure stabilizer, So that the lower end of the locking means can selectively introduce the high-pressure gas or the low-pressure gas.

Further, the valve may include: a valve A installed in a first gas replenishing line communicating with a channel between the inlet of the enthalpy increase device and the dispenser inlet; A valve (B) installed in a channel between the inlet of the enthalpy increasing device and the dispenser inlet; A valve (C) installed in a line between the outlet of the double variable capacity compressor and the inlet of the pressure stabilizer; A valve (D) installed in a channel between the inlet of the pressure stabilizer and the outlet of the dispenser; And a valve (E) installed in a second gas replenishing line communicating between the outlet of the enthalpy increasing device and the double variable displacement compressor, wherein the first gas replenishing line comprises a conduit between the valve (B) and the inlet of the enthalpy increasing device The outlet of the pressure stabilizer is in communication with the inlet of the first cylinder and the inlet of the pressure stabilizer is in communication with the conduit communicating between the valve C and the valve D, A third gas replenishing line communicating with the intake port of the cylinder, and a fourth gas replenishing line communicating with the noise chamber of the flange of the first cylinder group, and the valve E is installed in the fourth gas replenishing line.

Further, the valve may include: a valve A installed in a first gas replenishing line communicating with a channel between the inlet of the enthalpy increase device and the dispenser inlet; A valve (B) installed in a channel between the inlet of the enthalpy increasing device and the dispenser inlet; A valve (C) installed in a line between the outlet of the double variable capacity compressor and the inlet of the pressure stabilizer; And a valve (D) installed in a conduit between the inlet of the pressure stabilizer and the outlet of the dispenser, wherein the first gas supplement conduit is in communication with a conduit between the valve (B) and the inlet of the enthalpy increasing device, The inlet of the device is in communication with a conduit that connects the valve C and the valve D and the inlet of the first cylinder can be selectively in communication with the outlet of the pressure stabilizer or the outlet of the dispenser.

Further, the valve may be a valve (F), which is a three-way valve installed in a channel between the inlet of the enthalpy-increasing device and the dispenser inlet; A valve (G) which is a three-way valve installed in a channel between the dual variable capacity compressor and the distributor and communicating with the inlet of the pressure stabilizer; (E) installed in a second gas replenishing line communicating between the outlet of the enthalpy increasing device and the double variable capacity compressor, wherein the outlet of the valve (F) is in communication with the inlet of the enthalpy increasing device, and the valve F communicates with the dispenser inlet, the second inlet of the valve F communicates with the first gas replenishing line, the first inlet of the valve G communicates with the outlet of the double variable displacement compressor , The second inlet of the valve (G) communicates with the dispenser outlet, the outlet of the valve (G) communicates with the inlet of the pressure stabilizer, the outlet of the pressure stabilizer communicates with the inlet of the first cylinder, The gas replenishing line includes a third gas replenishing line communicating with the inlet port of the second cylinder and a fourth gas replenishing line communicating with the exhaust port of the first cylinder, and the valve E is installed in the fourth gas replenishing line.

Further, the valve may be a valve (F), which is a three-way valve installed in a channel between the inlet of the enthalpy-increasing device and the dispenser inlet; And a valve (G), which is a three-way valve installed in a channel between the dual variable capacity compressor and the distributor and communicating with the inlet of the pressure stabilizer, wherein the outlet of the valve (F) communicates with the inlet of the enthalpy increasing device , The first inlet of the valve F communicates with the dispenser inlet and the second inlet of the valve F communicates with the first gas replenishing line and the first inlet of the valve G communicates with the outlet of the double variable displacement compressor The second inlet of the valve G communicates with the dispenser outlet and the outlet of the valve G communicates with the inlet of the pressure stabilizer and the inlet of the first cylinder communicates with the outlet of the pressure stabilizer, And can selectively communicate with the outlet.

According to the technical solution of the present invention, the first through hole is formed in the wall surface of the first cylinder and the high pressure gas is introduced through the first through hole, so that the gas pressure at the upper end of the locking means is high. The lower end of the locking means can selectively introduce the high-pressure gas or the low-pressure gas, so that the gas pressure at the lower end of the locking means is switched between the high-pressure gas and the low-pressure gas. The pressure difference received by the locking means is a pressure difference between high and low pressure, and by switching to a high-low pressure, the dual-single variable capacity mode is stably switched to solve the stability problem that may occur when performing a single- .

BRIEF DESCRIPTION OF THE DRAWINGS A brief description of the drawings which form a part of this application is provided to aid the understanding of the present invention, and the exemplary embodiments of the present invention and the description thereof are intended to interpret the present invention and not to limit the present invention.
1 is a sectional view of a first embodiment of a double variable capacity compressor according to the present invention.
2 is an exploded view of a first embodiment of a dual variable displacement compressor according to the present invention.
3 is an exploded view of a second embodiment of a dual variable displacement compressor according to the present invention.
4 is a cross-sectional view of a third embodiment of a dual variable capacity compressor according to the present invention.
5 is an exploded view of a third embodiment of a dual variable displacement compressor according to the present invention.
6 is a dual variable capacity operation configuration diagram of a first embodiment of an air conditioning system according to the present invention.
Figure 7 is a single variable capacity operating configuration diagram of a first embodiment of an air conditioning system according to the present invention.
8 is a dual variable capacity operation configuration diagram of a second embodiment of an air conditioning system according to the present invention.
Figure 9 is a single variable capacity operating configuration diagram of a second embodiment of an air conditioning system according to the present invention.
10 is a dual variable capacity operation configuration diagram of a third embodiment of an air conditioning system according to the present invention.
11 is a diagram of a single variable capacity operation configuration of a third embodiment of an air conditioning system according to the present invention.
12 is a dual variable capacity operation configuration diagram of a fourth embodiment of an air conditioning system according to the present invention.
13 is a single variable capacity operation configuration diagram of a fourth embodiment of an air conditioning system according to the present invention.

It should be noted that the features of the embodiments and embodiments of the present application can be combined with one another under the premise that they do not collide. Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figs. 1 to 4, the present invention provides a double variable displacement compressor.

The dual variable capacity compressor includes a first cylinder group 10 and a second cylinder group 20 and the first cylinder group 10 and the second cylinder group 20 are arranged along the axial direction of the double variable capacity compressor do.

The first cylinder group 10 includes a first cylinder 11 having a first sliding slot 12 and a first through hole 12a. The first through hole 12a communicates with the first sliding slot 12 and is installed on the wall surface of the first cylinder 11 along the radial direction of the first cylinder 11 to introduce high pressure gas. The first sliding vane 14 is movably installed in the first sliding slot 12 and has a positioning groove 15 which is in contact with the outer circumferential surface of the eccentrically installed first roller 30. The locking means 16 is connected to the first through hole 12a at its upper end and can selectively introduce a high-pressure gas or a low-pressure gas into the positioning groove 15 so that the first sliding vane can be inserted into the positioning groove 15, Lock position to be locked away from the rotation center of the positioning groove 15 or an unlock position to be detached from the positioning groove 15. When the locking means 16 locks the first sliding vane 14, the first cylinder 11 idles and does not operate. When the locking means 16 is disengaged from the first sliding vane 14, the first sliding vane 14 is brought into contact with the outer circumferential surface of the first roller 30, and the first cylinder is operated.

The second cylinder group (20) includes a second cylinder (21) and a second sliding vane (23). The second cylinder 21 is provided with a second sliding slot 22 and the second sliding vane 23 is movably installed in the second sliding slot 22 and the second roller 40 And is always in contact with the outer peripheral surface. The second cylinder 21 is always in an operating state at the time of start-up and operation.

The first through hole 12a is formed in the wall surface of the first cylinder 11 and the high pressure gas flows through the first through hole 12a so that the gas pressure at the upper end of the locking means 16 is high. Since the lower end of the locking means 16 can selectively introduce a high-pressure gas or a low-pressure gas, the gas pressure at the lower end of the locking means 16 is switched between the high-pressure gas and the low-pressure gas. The pressure difference received by the locking means 16 is a pressure difference between the high pressure and the low pressure and the high and low pressure is switched to stably switch between the dual variable capacity mode and the single variable capacity mode, Stability problem.

The first sliding slot 12 is communicated with the high pressure of the housing to eliminate the need to mount the elastomer at the distal end of the sliding vane and can satisfy the lubricating action required when the sliding vane moves without providing a separate oil supply passage And there is no fear that sliding slots will accumulate oil and increase power consumption. Pressure gas or low-pressure gas flows into the lower end of the locking means 16 to switch the pressure, thereby simplifying the locking means and lowering the processing difficulty and the production cost.

Furthermore, the locking means 16 comprise a pin 16a and an elastomer 16b. The upper end of the pin 16a communicates with the first through hole 12a and the lower end of the pin 16a can selectively introduce the high-pressure gas or the low-pressure gas. The first cylinder 11 has an intake port 13b and a main intake port 13a and the lower end of the pin 16a communicates with the intake port 13b and the intake port 13b selectively receives high- can do. The elastomer 16b is in contact with the lower end of the pin 16a. The elastomer 16b is installed below the pin 16a and can provide an upward pressure against the pin 16a. In the present embodiment, the head portion of the fin does not need to be provided with the spring position restricting means.

1 to 5, the first cylinder group 10 further includes a flange 17 provided under the first cylinder 11, and the flange 17 is provided in the positioning groove 15 A mounting groove 18 is provided in the corresponding position along the axial direction of the dual variable capacity compressor and the pin 16a is movably installed in the mounting groove 18. [

2, the flange 17 has a flange gas guide hole 17a communicating with the first sliding slot 12 through an intake port 13b.

2, the first cylinder group 10 further includes a lower cover plate 19 connected to the bottom of the flange 17, and the lower cover plate 19 is connected to the gas guide And the inlet port 13b communicates with the lower end of the pin 16a through the flange gas guide hole 17a and the gas guide slot 19a of the lower cover plate.

2, a third through hole 17d is formed in the side wall of the noise chamber of the flange 17, and the third through hole 17d is communicated with the inlet of the second cylinder 21.

3, the first cylinder 11 is further provided with a through hole 11a, a flange 17 is provided with a connection hole 17e communicating with the noise chamber, and the through hole 11a ) Communicates with the noise chamber of the flange (17).

5, a fourth through hole 17b and a fifth through hole 17c are formed in the flange 17. The lower cover plate 19 is inserted into the guide slot 19a of the gas lower cover plate, The fourth through hole 17b is communicated with the lower end of the pin 16a through the fifth through hole 17c and the gas guide slot 19a of the lower cover plate and the fourth through hole 17b is communicated with the lower end of the pin 16a, A high-pressure gas or a low-pressure gas can be selectively introduced.

2, the second cylinder 21 has a sixth through-hole 24, and the sixth through-hole 24 is formed in the second cylinder 21 along the radial direction of the second cylinder 21 21, so that the sixth through hole 24 is communicated with the second sliding slot 22. As shown in FIG.

The present invention also provides an air conditioning system including a dual variable displacement compressor (50), wherein the dual variable displacement compressor (50) is identical to the dual variable displacement compressor.

6-13, the air conditioning system includes an enthalpy increasing device 60 in communication with a dual variable capacity compressor 50, a pressure stabilizer 70, a frequency divider 80, and a dual variable capacity compressor 50 ), An enthalpy increasing device (60), and a valve for turning on and off a channel between the pressure stabilizer (70) and the dispenser (80) so that the lower end of the locking means (16) .

Specifically, as shown in FIGS. 1 and 2, the distal end of the first sliding slot 12 communicates with the high pressure inside the housing through the first through hole 12a. The intake port 13b communicates with the intake port 13a of the first cylinder 11 and is connected to a pin (not shown) filled with the elastomer 16b through the flange gas guide hole 17a and the gas guide slot 19a of the lower cover plate 16a. In the double operation mode, the upper end of the pin 16a is the high pressure of the housing, the lower end of the pin 16a is the intake pressure of the first cylinder 11, that is, the lower cylinder, And when the pin 16a is released, the first sliding vane 14 is normally operated.

In the double variable capacity compressor according to another embodiment, the third through hole 17d is formed in the side wall of the noise chamber of the flange 17, and the exhaust gas of the first cylinder 11, that is, the exhaust gas of the primary cylinder, Through the through hole 17d to be mixed with the enthalpy increasing gas and then mixed with the enthalpy increasing gas and then introduced into the intake chamber of the second cylinder 21 through the intake port of the second cylinder 21, .

In the single variable capacity operation mode, the pressure of the intake port 13b of the first cylinder 11 is switched to the high pressure by the varactor, that is, the upper end which is the head portion of the pin 16a and the lower end portion which is the distal end portion of the pin 16a The pin 16a is moved upward under the action of the spring force to lock the first sliding vane 14 of the first cylinder 11 and the first cylinder 11, that is, the lower cylinder is disengaged.

4 and 5, in this embodiment, the distal end of the first sliding slot 12 of the first cylinder 11 communicates with the high pressure inside the housing through the first through hole 12a. The fourth through hole 17b and the fifth through hole 17c are further provided in the flange 17 and the fourth through hole 17b is directly connected to the external buffer chamber and the fifth through hole 17c To the gas guide slot 19a of the lower cover plate and communicates with the lower end of the pin 16a. In the double operation mode, the upper end which is the head portion of the pin 16a is the high pressure of the housing, the lower end portion which is the distal end portion of the pin 16a is the intake pressure, the pressure difference which the pin 16a receives is the high- The first sliding vane 14 is normally operated. The exhaust gas of the primary cylinder 11, that is, the exhaust gas of the first cylinder 11 passes through the primary exhaust gas passage and through the intake port of the second cylinder 21 to the intake chamber of the upper cylinder, Enters the chamber and performs secondary compression.

In the single variable capacity operating mode, the pressure of the fourth through hole 17b of the flange 17 is switched to high pressure by the varactor, that is, both the head portion and the distal portion of the pin are at a high pressure, Move it up to lock the sliding vane of the lower cylinder, and the lower cylinder is detached.

Here, as shown in FIGS. 6 and 7, the valve is provided with a valve A installed in a first gas replenishing line communicating with a channel between the inlet of the enthalpy increasing device 60 and the inlet of the distributor 80; A valve B installed in a channel between the inlet of the enthalpy increasing device 60 and the inlet of the distributor 80; A valve C installed in a line between the outlet of the double variable displacement compressor 50 and the inlet of the pressure stabilizer 70; A valve D installed in a conduit between the inlet of the pressure stabilizer 70 and the outlet of the distributor 80; (E) installed in a second gas replenishing line communicating between the outlet of the enthalpy increasing device (60) and the double variable displacement compressor (50), wherein the first gas replenishing line comprises a valve (B) The outlet of the pressure stabilizer 70 communicates with the inlet 13b of the first cylinder 11 and the inlet of the pressure stabilizer 70 communicates with the valve C The second gas replenishing line communicates with a third gas replenishing line communicating with the inlet port of the second cylinder 21 and a fourth gas communicating with the exhaust port of the first cylinder 11, And the valve E is installed in the fourth gas supplement pipe line.

Alternatively, as shown in Figs. 8 and 9, the valve may include a valve A installed in a first gas replenishing line communicating with a channel between the inlet of the enthalpy increasing device 60 and the inlet of the distributor 80; A valve B installed in a channel between the inlet of the enthalpy increasing device 60 and the inlet of the distributor 80; A valve C installed in a line between the outlet of the double variable displacement compressor 50 and the inlet of the pressure stabilizer 70; And a valve D installed in a conduit between the inlet of the pressure stabilizer 70 and the outlet of the distributor 80. The first gas replenishment conduit is connected to the valve B and the enthalpy increasing device 60 And the inlet of the pressure stabilizer 70 communicates with a conduit communicating between the valve C and the valve D. The intake port 13b of the first cylinder 11 communicates with the pressure stabilizer (70) or the outlet of the dispenser (80).

As shown in Fig. 6, valve A, valve D and valve E are opened and valve B and valve C are closed in the dual variable capacity operation mode. The lower end of the pin 16a that locks the first sliding vane 14 is directly connected to the first cylinder 11, that is, the first cylinder 11, And communicates with the intake port 13b. The intake port 13b of the first cylinder 11 communicates with the intake pressure by opening the valve D and the pin 16a moves down under the action of the high and low pressure pressure difference so that the first sliding vane 14 normally . The medium pressure exhaust gas compressed and formed by the first cylinder 11 is mixed with the medium pressure supplemental gas through the valve A in the enthalpy increasing device 60 by opening the valve E, The high pressure exhaust gas formed by compressing the medium pressure gas by the second cylinder 21 enters the exhaust pipe inside the housing of the compressor and is discharged to the air conditioning system, thereby realizing a dual variable capacity operation mode.

As shown in Fig. 7, valve A, valve D and valve E are closed and valve B and valve C are opened in the single variable capacity operation mode. The lower end of the pin 16a that locks the first sliding vane 14 is communicated with the intake port 13b of the first cylinder 11 in communication with the high pressure of the housing as the open structure of the first sliding slot 12, And the intake port 13b of the first cylinder 11 communicates with the high-pressure gas by opening the valve C and the pin 16a is moved upward under the action of the elastomer 16b, that is, the spring force, 14 are locked and the first cylinder 11 is disengaged. The low-pressure gas enters the intake port of the second cylinder 21 via the valve B, and the high-pressure exhaust gas formed by compressing the low-pressure gas by the second cylinder 21 enters the exhaust pipe inside the housing of the compressor, A single variable capacity mode of operation is realized.

As shown in Fig. 8, in the double variable capacity operation mode, the valve A and the valve D are opened, and the valve B and the valve C are closed. The lower end of the pin 16a that locks the first sliding vane 14 communicates with the inlet of the primary cylinder 11, that is, the inlet port of the first cylinder 11, (13b) and communicates with the intake pressure by opening the valve (D). The pin 16a is moved downward under the action of the high-low-pressure pressure difference so that the first sliding vane 14 is normally operated. The intake port 13b of the first cylinder 11 directly communicates with the distributor 80. The medium pressure exhaust gas compressed and formed by the primary cylinder 11, Pressure discharge gas which is mixed with the medium-pressure supplemental gas passed through the valve (A) in the first cylinder (60) and then enters the intake port of the second cylinder (21) Enters the internal exhaust pipe and is discharged to the air conditioning system, thereby realizing a dual variable capacity operation mode.

9, valve A and valve D are closed and valve B and valve C are opened in a single variable capacity mode of operation. The lower end of the pin 16a that locks the first sliding vane 14 is communicated with the intake port 13b of the first cylinder 11 in communication with the high pressure of the housing as the opening structure of the first sliding slot 12, And the pin 16a is moved upward under the action of the spring force to lock the first sliding vane 14 and the first cylinder 11 is disengaged. The low pressure gas of the first cylinder 11 and the low pressure gas of the valve B are introduced into the intake port of the high pressure cylinder and the intake port 13b of the first cylinder 11 is communicated with the low pressure gas of the high pressure cylinder, Pressure discharge gas formed by compressing the low-pressure gas by the compressor 21 enters the exhaust pipe inside the housing of the compressor and is discharged to the air-conditioning system, thereby realizing a single variable capacity operation mode.

The valve A and the valve B, the valve C and the valve D can be replaced with a three-way valve or a four-way valve, respectively, so as to be convenient to mount. The details are as follows.

The valve comprises a valve F which is a three-way valve installed in a channel between the inlet of the enthalpy increase device 60 and the inlet of the distributor 80; A valve G which is a three-way valve installed in a pipeline between the double variable displacement compressor 50 and the distributor 80 and communicated with the inlet of the pressure stabilizer 70; (E) installed in a second gas replenishing line communicating between the outlet of the enthalpy increasing device (60) and the double variable displacement compressor (50), and the outlet of the valve (F) The first inlet of the valve F is in communication with the inlet of the dispenser 80 and the second inlet of the valve F is in communication with the first gas replenishing line and the first inlet of the valve F is in communication with the inlet, The second inlet of the valve G communicates with the outlet of the dispenser 80 and the outlet of the valve G communicates with the inlet of the pressure stabilizer 70 The outlet of the pressure stabilizer 70 communicates with the intake port 13b of the first cylinder 11 and the second gas replenishment conduit is communicated with the intake port of the second cylinder 21, And a fourth gas replenishing line communicating with the exhaust port of the first cylinder (11), and the valve (E) is installed in the fourth gas replenishing line.

Alternatively, the valve may be a valve F, which is a three-way valve installed in a conduit between the inlet of the enthalpy increase device 60 and the inlet of the distributor 80; And a valve G which is a three-way valve installed in a pipeline between the double variable-capacity compressor 50 and the distributor 80 and communicated with the inlet of the pressure stabilizer 70, The first inlet of the valve F communicates with the inlet of the distributor 80 and the second inlet of the valve F communicates with the first gas replenishment conduit , The first inlet of the valve G communicates with the outlet of the dual variable displacement compressor 50 and the second inlet of the valve G communicates with the outlet of the dispenser 80 and the outlet of the valve G communicates And the inlet 13b of the first cylinder 11 can be selectively communicated with the outlet of the pressure stabilizer 70 or the outlet of the distributor 80. [

In the present invention, the low-temperature heating capability is ensured through the double enthalpy increase compression technique, and the high-low pressure is switched through the variable displacement switching means to stably switch the double-single variable displacement mode, . This technique improves the efficiency when the dual variable capacity compressor operates in the light load operation mode and compensates for the efficiency failure in the light load operation mode of the dual variable capacity compressor so that it can not be stably switched to the single variable capacity mode It is possible to solve the problem that the oil accumulates in the sliding slot of the cylinder. Both the first sliding slot 12 and the second sliding slot 22 are open, communicating with the high pressure of the housing, and are more reliable.

As described above, in the embodiment of the present invention, the first through hole 12a is formed on the wall surface of the first cylinder 11, and by introducing the high pressure gas through the first through hole 12a, And the gas pressure at the upper end of the cylinder 16 is high. The lower end of the locking means 16 can selectively introduce a high pressure gas or a low pressure gas so that the gas pressure at the lower end of the locking means 16 is switched between the high pressure gas and the low pressure gas, , And in the absence of a gas pressure difference, the pin locks the sliding vane so that a single variable displacement operation is achieved. The pressure differential received by the locking means 16 is a pressure difference between high and low pressure and can occur when performing a single-to-double variable capacity transition in the prior art by stably switching between dual variable capacity mode and single variable capacity mode, And solved the stability problem.

The foregoing is merely a preferred embodiment of the present invention, and it is not intended to limit the present invention, and various changes and modifications may be made by those skilled in the art. All modifications, equivalents, and improvements within the spirit and scope of the present invention are included in the scope of protection of the present invention.

Claims (16)

A dual variable capacity compressor comprising a first cylinder group (10) and a second cylinder group (20) arranged along the axial direction of a dual variable capacity compressor,
The first cylinder group (10)
A first through hole 12a communicating with the first sliding slot 12 and the first sliding slot 12 and flowing high pressure gas to the wall surface of the first cylinder 11 along the first cylinder 11 A first cylinder (11) provided with the first cylinder (11);
A first sliding vane (14) movably installed in the first sliding slot (12), the first sliding vane (14) being in contact with an outer circumferential surface of the eccentrically installed first roller (30) and having a positioning groove (15);
The upper end portion is communicated with the first through hole 12a and the lower end portion can selectively introduce the high-pressure gas or the low-pressure gas so that the first sliding vane can be inserted into the positioning groove 15 to rotate the first roller And a locking means (16) having a locking position for locking away from the center or an unlocking position for releasing from said positioning groove (15)
The second cylinder group 20
A second cylinder 21 provided with a second sliding slot 22;
And a second sliding vane (23) that is always in contact with an outer circumferential surface of the second roller (40) which is movably installed in the second sliding slot (22) and eccentrically installed. The method according to claim 1,
Characterized in that the locking means (16) comprises a pin (16a) whose upper end is in communication with the first through hole (12a) and whose lower end is capable of selectively introducing a high pressure gas or a low pressure gas. 3. The method of claim 2,
The first cylinder (11)
A communicating inlet 13b and a main inlet 13a;
And an elastomer (16b) which is in contact with the lower end of the pin (16a)
Wherein the lower end of the pin (16a) communicates with the intake port (13b), and the intake port (13b) is capable of selectively introducing a high-pressure gas or a low-pressure gas. The method of claim 3,
Wherein the first cylinder group (10) further comprises a flange (17) provided below the first cylinder (11) and the flange (17) is located at a position corresponding to the positioning groove (15) Wherein a mounting groove (18) is provided along the axial direction of the capacity compressor, and the pin (16a) is movably installed in the mounting groove (18). 5. The method of claim 4,
Wherein the flange (17) has a flange gas guide hole (17a) communicating with the first sliding slot (12) through the intake port (13b). 6. The method of claim 5,
The first cylinder group further includes a lower cover plate 19 connected to the bottom of the flange 17 and the lower cover plate 19 has a gas guide slot 19a of the lower cover plate, The inlet port 13b communicates with the lower end of the pin 16a through the flange gas guide hole 17a and the gas guide slot 19a of the lower cover plate. 5. The method of claim 4,
A third through hole 17d is formed in the side wall of the noise chamber of the flange 17 and the third through hole 17d is communicated with the air inlet of the second cylinder 21. The double variable capacity compressor . 5. The method of claim 4,
A through hole 11a is further formed in the first cylinder 11. A connection hole 17e communicating with the noise chamber of the flange 17 is provided on the flange 17, 11a communicate with a noise chamber of said flange (17). 5. The method of claim 4,
A fourth through hole 17b and a fifth through hole 17c are formed in the flange 17 and the lower cover plate 19 of the first cylinder group 10 is inserted into the gas guide slot And the fourth through hole 17b communicates with the lower end of the pin 16a through the fifth through hole 17c and the gas guide slot 19a of the lower cover plate, The through hole (17b) is capable of selectively introducing a high-pressure gas or a low-pressure gas. The method according to claim 1,
The second cylinder (21) has a sixth through hole (24) installed on the wall surface of the second cylinder (21) along the radial direction of the second cylinder (21) 6 through-hole (24) communicates with said second sliding slot (22). An air conditioning system comprising a dual variable displacement compressor (50) according to any of the preceding claims. 12. The method of claim 11,
An enthalpy increasing device 60 in communication with the double variable displacement compressor 50, a pressure stabilizer 70 and a distributor 80 and the double variable displacement compressor 50, the enthalpy increasing device 60, Further comprising a valve for turning on and off a conduit between the gas supply line (70) and the dispenser (80) so that the lower end of the locking means (16) can selectively introduce the high pressure gas or the low pressure gas. 13. The method of claim 12,
Wherein the valve comprises:
A valve (A) installed in a first gas replenishing line communicating with an inlet of the enthalpy increasing device (60) and an inlet of the distributor (80);
A valve (B) installed in a conduit between the inlet of the enthalpy increasing device (60) and the inlet of the dispenser (80);
A valve C installed in a conduit between the outlet of the double variable displacement compressor 50 and the inlet of the pressure stabilizer 70;
A valve (D) installed in a conduit between the inlet of the pressure stabilizer (70) and the outlet of the dispenser (80);
And a valve (E) installed in a second gas replenishing line communicating between the outlet of the enthalpy increasing device (60) and the double variable capacity compressor (50)
The first gas supplementing line communicates with a conduit between the valve B and the inlet of the enthalpy increasing device 60 and the outlet of the pressure stabilizing device 70 is connected to the inlet of the first cylinder 11 The inlet of the pressure stabilizer 70 communicates with a conduit communicating between the valve C and the valve D and the second gas replenishing conduit is communicated with the conduit of the second cylinder 21 A third gas replenishing line communicating with the inlet port and a fourth gas replenishing line communicating with the noise chamber of the flange (17) of the first cylinder group (10), the valve (E) being connected to the fourth gas replenishing line Is installed in the air conditioning system. 13. The method of claim 12,
Wherein the valve comprises:
A valve (A) installed in a first gas replenishing line communicating with an inlet of the enthalpy increasing device (60) and an inlet of the distributor (80);
A valve (B) installed in a conduit between the inlet of the enthalpy increasing device (60) and the inlet of the dispenser (80);
A valve C installed in a conduit between the outlet of the double variable displacement compressor 50 and the inlet of the pressure stabilizer 70;
And a valve (D) installed in a channel between the inlet of the pressure stabilizer (70) and the outlet of the dispenser (80)
The first gas supplement conduit communicates with the conduit between the valve B and the inlet of the enthalpy increasing device 60 and the inlet of the pressure stabilizer 70 is connected between the valve C and the valve D Characterized in that the intake port (13b) of the first cylinder (11) communicates with the outlet of the pressure stabilizer (70) or the outlet of the divider (80) Air conditioning system. 13. The method of claim 12,
Wherein the valve comprises:
A valve F which is a three-way valve installed in a channel between the inlet of the enthalpy increasing device 60 and the inlet of the distributor 80;
A valve (G), which is a three-way valve installed in a conduit between the double variable displacement compressor (50) and the frequency divider (80) and communicating with the inlet of the pressure stabilizer (70);
And a valve (E) installed in a second gas replenishing line communicating between the outlet of the enthalpy increasing device (60) and the double variable capacity compressor (50)
The outlet of the valve F is in communication with the inlet of the enthalpy increasing device 60 and the first inlet of the valve F is in communication with the inlet of the divider 80, 2 inlet communicates with a first gas replenishing line, a first inlet of the valve (G) communicates with an outlet of the double variable displacement compressor (50), and a second inlet of the valve (G) The outlet of the valve G communicates with the inlet of the pressure stabilizer 70 and the outlet of the pressure stabilizer 70 communicates with the inlet of the first cylinder 11 And the second gas replenishing line includes a third gas replenishing line communicating with the inlet port of the second cylinder 21 and a fourth gas replenishing line communicating with the exhaust port of the first cylinder 11 , And the valve (E) is installed in the fourth gas supplement pipe. 13. The method of claim 12,
Wherein the valve comprises:
A valve F which is a three-way valve installed in a channel between the inlet of the enthalpy increasing device 60 and the inlet of the distributor 80;
And a valve (G), which is a three-way valve installed in a channel between the double variable displacement compressor (50) and the frequency divider (80) and communicated with an inlet of the pressure stabilizer (70)
The outlet of the valve F is in communication with the inlet of the enthalpy increasing device 60 and the first inlet of the valve F is in communication with the inlet of the divider 80, 2 inlet communicates with a first gas replenishing line, a first inlet of the valve (G) communicates with an outlet of the double variable displacement compressor (50), and a second inlet of the valve (G) The outlet of the valve G communicates with the inlet of the pressure stabilizer 70 and the inlet 13b of the first cylinder 11 communicates with the inlet of the pressure stabilizer 70. [ And the outlet of the dispenser (80).

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